Cardiopulmonary echocardiographic exercise test for defining subendocardial dysfunction

    Authors

    Keywords

    quantitative stress echocardiography, exercise gas exchange, subendocardial dysfunction

    DOI

    https://doi.org/10.15836/ccar2024.490

    Full Text

    **Introduction**: Quantitative stress echocardiography provides sensitive markers for diagnosing subendocardial dysfunction but its specifity is low. (1, 2) We combine exercise gas exchange measurements with quantitative stress echocardiography in order to better distinguish between ischemic and non-ischemic causes of myocardial dysfunction. **Patients and Methods:** We describe the method of the cardiopulmonary echocardiographic exercise test (CPEET) and provide examples that differentiate between ischemic and non-ischemic substrates. In 35 patients, we correlated peak strain rate, peak systolic myocardial velocity, and peak left ventricular filling pattern with gas exchange parameters: pVO2, dVO2/dWR, pO2 pulse, AtPETCO2, and VE/VCO2 slope during exercise test. Statistical analysis was performed using SPSS Statistics for Windows version 25. The values of p 2, AtVO2, dVO2/dWR, pO2 pulse, AtPETCO2 and negatively with VE/VCO2 slope. pVs correlates positively with pVO2, AtVO2, O2 pulse, dVO2/dWR, AtPETCO2, and negatively with VE/VCO2 slope. Correlation of pSR with pV02 and dV02/dWR is stronger than correlation of Vs, respectively. pE/e ratio correlates negatively with pVO2, AtVO2, PETCO2 and positively with VE/VCO2 slope. **Conclusion**: Combining pSR/pVs with peak VO2, dVO2/dWR, and peak oxygen pulse may better distinguish ischemic from non-ischemic substrate. Additionally, other exercise gas exchange parameters combined with stress echo-derived metrics could enhance the diagnosis of pathophysiological conditions, such as reduced exercise peak VO2 and reduced SR/Vs.

    Literature

    1. Santoro C, Sorrentino R, Esposito R, Lembo M, Capone V, Rozza F, et al. Cardiopulmonary exercise testing and echocardiographic exam: an useful interaction. Cardiovasc Ultrasound. 2019 December 3;17(1):29. https://doi.org/10.1186/s12947-019-0180-0
    2. Chaudhry S, Arena RA, Hansen JE, Lewis GD, Myers JN, Sperling LS, et al. The utility of cardiopulmonary exercise testing to detect and track early-stage ischemic heart disease. Mayo Clin Proc. 2010 October;85(10):928–32. https://doi.org/10.4065/mcp.2010.0183
    Cardiologia Croatica
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    Cardiopulmonary echocardiographic exercise test for defining subendocardial dysfunction

    Extended Abstract
    Issue11-12
    Published
    Pages490
    PDF via DOIhttps://doi.org/10.15836/ccar2024.490
    quantitative stress echocardiography
    exercise gas exchange
    subendocardial dysfunction

    Authors

    Ana Fabris*ORCIDThe Sveti Nikola Polyclinic, Korčula, Croatia
    Mila JakovljevićORCIDThe Sveti Nikola Polyclinic, Korčula, Croatia
    Marija Pleško AvšarORCIDThe Sveti Nikola Polyclinic, Korčula, Croatia

    *Correspondence email: fabrisana@yahoo.com

    Full Text

    Introduction: Quantitative stress echocardiography provides sensitive markers for diagnosing subendocardial dysfunction but its specifity is low. (1, 2) We combine exercise gas exchange measurements with quantitative stress echocardiography in order to better distinguish between ischemic and non-ischemic causes of myocardial dysfunction.

    Patients and Methods: We describe the method of the cardiopulmonary echocardiographic exercise test (CPEET) and provide examples that differentiate between ischemic and non-ischemic substrates. In 35 patients, we correlated peak strain rate, peak systolic myocardial velocity, and peak left ventricular filling pattern with gas exchange parameters: pVO2, dVO2/dWR, pO2 pulse, AtPETCO2, and VE/VCO2 slope during exercise test. Statistical analysis was performed using SPSS Statistics for Windows version 25. The values of p < 0.05 were considered statistically significant.

    Results: Peak strain rate correlates positively with pVO2, AtVO2, dVO2/dWR, pO2 pulse, AtPETCO2 and negatively with VE/VCO2 slope. pVs correlates positively with pVO2, AtVO2, O2 pulse, dVO2/dWR, AtPETCO2, and negatively with VE/VCO2 slope. Correlation of pSR with pV02 and dV02/dWR is stronger than correlation of Vs, respectively. pE/e ratio correlates negatively with pVO2, AtVO2, PETCO2 and positively with VE/VCO2 slope.

    Conclusion: Combining pSR/pVs with peak VO2, dVO2/dWR, and peak oxygen pulse may better distinguish ischemic from non-ischemic substrate. Additionally, other exercise gas exchange parameters combined with stress echo-derived metrics could enhance the diagnosis of pathophysiological conditions, such as reduced exercise peak VO2 and reduced SR/Vs.

    Literature

    1. 1.
      Santoro C, Sorrentino R, Esposito R, Lembo M, Capone V, Rozza F, et al. Cardiopulmonary exercise testing and echocardiographic exam: an useful interaction. Cardiovasc Ultrasound. 2019 December 3;17(1):29.DOI
    2. 2.
      Chaudhry S, Arena RA, Hansen JE, Lewis GD, Myers JN, Sperling LS, et al. The utility of cardiopulmonary exercise testing to detect and track early-stage ischemic heart disease. Mayo Clin Proc. 2010 October;85(10):928–32.DOI